Application of Direct Analysis in Real Time–High Resolution Mass

Sep 17, 2018 - ... Spectrometry to Investigations of Induced Plant Chemical Defense Mechanisms—Revelation of Negative Feedback Inhibition of an Alli...
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Application of Direct Analysis in Real Time-High Resolution Mass Spectrometry to Investigations of Induced Plant Chemical Defense Mechanisms—Revelation of Negative Feedback Inhibition of an Alliinase Tianyu He, Megan I. Chambers, and Rabi Ann Musah Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.8b03295 • Publication Date (Web): 17 Sep 2018 Downloaded from http://pubs.acs.org on September 19, 2018

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Analytical Chemistry

Application of Direct Analysis in Real Time-High Resolution Mass Spectrometry to Investigations of Induced Plant Chemical Defense Mechanisms—Revelation of Negative Feedback Inhibition of an Alliinase Tianyu He, Megan Isabella Chambers and Rabi Ann Musah* Department of Chemistry, State University of New York at Albany, 1400 Washington Avenue, Albany, NY, 12222, USA *Corresponding author Rabi Musah Department of Chemistry, State University of New York at Albany, 1400 Washington Avenue, Albany, NY 12222, USA Tel: 518-269-0607 Email: [email protected]

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Abstract Several plants of agricultural and medicinal importance utilize defense chemistry that involves deployment of highly labile, reactive and lachrymatory organosulfur molecules. However, this chemistry is difficult to investigate because the compounds are often short-lived and prone to degradation under the conditions required for analysis by common analytical techniques. This issue has complicated efforts to study the defense chemistry of plants that exploit the use of sulfur in their defense arsenals. This work illustrates how direct analysis in real time-high resolution mass spectrometry (DART-HRMS) can be used to track organosulfur defense compound chemistry under mild conditions. Petiveria alliacea was used a model plant that exploits the enzyme alliinase to generate induced organosulfur compounds in response to herbivory. Tracking of the organosulfur compounds it produces and quantifying them by DART-HRMS using isotopically-labeled analogues, revealed a feedback inhibition loop through which the activities of the alliinase are stymied shortly after their activation. The results show that the downstream thiosulfinate product petivericin (100 µM) and pyruvate (8.4 mM) inhibit alliinase activity by 60% and 29%, respectively after 1 h, and a mixture of the two inhibited alliinase activity by 65%. By 2 h, alliinase activity in the presence of these alliinase-derived products had ceased completely. Since thiosulfinate, pyruvate and lachrymatory sulfine compounds are produced via the same alliinase-derived sulfenic acid intermediate, the inhibition of alliinase activity by increasing concentrations of downstream products shows how production of these defense compounds is modulated in real-time in response to a tissue breach. These findings provide a framework within which heretofore unexplained phenomena observed in the defense chemistry of P. alliacea, onion, garlic, and other plants can be explained, and an approach by which to track labile compounds as well as enzymatic activity by DART-HRMS.

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Analytical Chemistry

Introduction Plants have evolved a wide range of mechanisms to ward off herbivores and microbial infections. Those that are chemically based can be either constitutive (i.e. the defense molecules are always present), or induced, meaning that they are generated and deployed in response to tissue injury. Plant chemical defense mechanisms that exploit induced formation of organosulfur compounds are difficult to study by many conventional methods because of the lability of the organosulfur compounds themselves. For example, GC-MS methods that are commonly used to track the formation of defense compounds result in artifacts derived from reactions that organosulfur compounds undergo in the GC injection port.1-10 This leads to incorrect conclusions not only about the identities of the molecules present, but also about the details of the steps in the chemical defense strategy. Method-induced artifact formation continues to hamper studies of the mechanisms by which a number of well-known plants of culinary and medicinal importance initiate and curtail the formation of these molecules when tissue injury occurs. Plants that utilize “Allium chemistry” serve as a case in point. Onion (Allium cepa), garlic (A. siculum) and the Amazonian medicinal plant Petiveria alliacea are species that utilize thiosulfinates (R-S(=O)S-R) and lachrymatory sulfines (R-CH=S=O) as defense compounds.11-15 As is illustrated in Scheme 1, they are formed as part of a complex network of S-substituted cysteine sulfoxide-derived defensive secondary metabolites that include vesicant thiosulfinates, oligosulfides, thiosulfonates, trithiolanes, cepaenes, zwiebelanes, aldehydes, elemental sulfur and other small inorganic signaling molecules such as H2S and SO2.16,17 These compounds are produced when the previously compartmentalized pyridoxal phosphate (PLP)-dependent C-S lyase (i.e. alliinase) is exposed to constitutively present S-substituted cysteine sulfoxides as a consequence of tissue disruption. As illustrated in Scheme 1, lachrymator production in response to herbivore challenge begins with exposure of cytoplasmic cysteine sulfoxide precursors to previously compartmentalized vacuolar alliinase enzymes. The first stable and easily isolatable products formed from this interaction are pyruvate and thiosulfinate compounds. The pyruvate is formed from α-aminoacrylic acid, whereas the thiosulfinates occur through condensation of two molecules of the sulfenic acid intermediate that is initially formed by alliinase-mediated cleavage of S-substituted cysteine sulfoxides. The presence of lachrymatory factor synthase (LFS)15,18-20 is crucial for the production of the volatile sulfine lachrymators. The lachrymators are unstable in the aqueous medium in which they are formed and are quickly hydrolyzed to the corresponding aldehydes.21 The organosulfur derivatives formed through the action of alliinase are reactive and susceptible to attack by oxygen, nitrogen and sulfur nucleophiles.22-26 Extracts of plants that produce these compounds are known to be destructive to living tissue and to cause contact dermatitis, blisters, and chemical burns.27-32 A number of studies have also shown that some of these compounds elicit painful inflammatory responses in animal predators through activation of TRPA1 and TRPV1, two temperature activated ion channels that are present in the pain-sensitive neurons that activate the mouth.33-37 For these reasons, the utilization of this type of weaponry in plants is potentially problematic because of the collateral damage it can cause. The electrophilicity of the various defense compounds makes them corrosive and/or highly reactive. This, coupled with their non-specificity towards reactions with cellular nucleophiles, renders plant cells at the site of injury susceptible to indiscriminate attack by the very defense compounds produced to ward off predators. This scenario presents plants that utilize alliinase-mediated defense chemistry with a dilemma: how to mount an effective assault against a diverse population of attackers (e.g. vertebrate herbivores or insects), while minimizing self-damage caused by the continued formation of corrosive lachrymators and other electrophilic organosulfur compounds. The threat of incursions by pathogenic microbes at the site of injury adds another layer of complexity to the problem. Historically, the monitoring of how formation of labile organosulfur defense compounds is curtailed has been challenged because of analysis method-induced transformations which form artifacts. 3 ACS Paragon Plus Environment

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Direct analysis in real time-high resolution mass spectrometry (DART-HRMS) and proton transfer reaction mass spectrometry (PTR-MS) have been shown to be well-suited for the detection of labile organosulfur compounds, without promoting their degradation or the formation of artifacts that has been observed by GC-MS.13,38-41 For example, PTR-MS has been used to detect and track volatile organosulfur compounds emitted from several Brassica species in response to herbivory.38,39,41,42 In addition, Samudrala et al. have reported optimized conditions for the observation of such compounds in plants using this technique.40 DART-HRMS was used to demonstrate for the first time the formation of fleeting sulfenic acid intermediates formed in onion and garlic on tissue injury.13 It has also been used to reveal how the roots of Mimosa pudica emit a spray of noxious organosulfur compounds in response to touch.43 We report here how DART-HRMS and isotopically-labeled precursor and product molecules can be used to readily track and quantify the formation of induced labile organosulfur defense compounds in a manner that reveals information about the impact of defense molecules on the proteins that mediate their formation. Following this approach and using P. alliacea as a model, DART-HRMS monitoring of plant-derived alliinase-mediated breakdown of a precursor cysteine sulfoxide illustrated a novel negative feedback inhibition by which molecules downstream of alliinase ultimately inhibit its function. Experimental Section Materials. Pyruvate-d3 was purchased from Cambridge Isotopes Laboratories, Inc (Tewksbury, MA). mChloroperoxybenzoic acid (m-CPBA) was purchased from Fisher Scientific (Hampton, NH). Coomassie (Bradford) Protein Assay Kit was purchased from Thermo Scientific (Rockford, IL). Biotage SNAP Ultra Cartridges were purchased from Biotage (Charlotte, NC). Methylene chloride and hexanes were acquired from Pharmco-Aaper (Brookfield, CT). Dibenzyl disulfided14 was synthesized from benzyl chloride-d7. Its synthetic route is outlined in Supporting Information Figure S-1, and its characterization is also described in the Supporting Information section. All other chemicals were obtained from Sigma-Aldrich (St. Louis, MO). P. alliacea alliinase/LFS were extracted according to the method of Musah et al.,20 with minor modifications. Whole fresh P. alliacea plants were obtained from Native Habitat Landscaping (Vero Beach, FL). Confirmation of alliinase activity in P. alliacea roots. Woody P. alliacea roots were harvested from the plant and after tissue disruption were immediately analyzed using DART-HRMS in both positive and negative ion modes at 350 oC. Spectra were acquired by suspending the samples in the open-air space between the ion source and mass spectrometer inlet. Mass spectral acquisition and data processing. DART-HRMS mass spectra of the synthesized compounds and calibration standards were acquired using a DART-SVPTM ion source (IonSense, Saugus, MA) coupled to a JEOL AccuTOF high resolution time-of-flight mass spectrometer (JEOL USA, Peabody, MA). Petivericin and petiveriin calibration standards were analyzed in positive-ion mode, while the pyruvate calibration standard was analyzed in negative ion mode. The parameters for the DART ion source were: grid voltage, 250 V; and gas heater temperature, 350 °C. The settings for the mass spectrometer were: ring lens voltage, 5 V (-5 V for negative ion mode); orifice 1 voltage, 20 V (20 V for negative ion mode); orifice 2 voltage, 5 V (-5 V for negative ion mode); and peak voltage, 600 V. Spectra were collected over the m/z range 60-800 at a rate of 1 spectrum/s. The ion source was operated with ultra-high purity helium (Airgas, Albany, NY) at a flow rate of 2 L/min and the resolving power of the mass spectrometer was 6000 FWHM. A 12 DIP-it® sampler (IonSense, Saugus, MA) was used to automate the analysis of the calibration standards (described below and in Supporting Information Figure S-2). Poly(ethyleneglycol) (PEG; average MW 600) 4 ACS Paragon Plus Environment

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Analytical Chemistry

was analyzed with every acquired spectrum as a standard for accurate mass determinations. TSSPro 3 software (Shrader Analytical, Detroit, MI) was used for data processing including averaging, centroiding, background subtraction and integration. Semi-automated analysis protocol. A 12 DIP-it® sampler (IonSense, Saugus, MA) was used to automate the analysis of the calibration standards (described below and in Supporting Information Figure S-2). Utilization of a linear rail system within which the Dip-it tips were mounted allowed for reproducibility between sample replicates. In order to detect the analytes of interest by DART-HRMS, it was determined that amounts of ≥ 0.786 ng were required, because samples of less than this amount did not yield ion chromatograms that were consistent enough to enable quantification. In this case, this was generally equivalent to 1.5 µL of a 2 µM solution of the calibration standards or the protein extract. This volume was deposited onto the tip of the capillary tube of each DIP-it® Tip. The tips were mounted at the same height in the linear-rail with the tips oriented so that the applied sample was facing the DART gas stream. Once the solution was applied to the tips, it was allowed to dry before DART-HRMS analysis, in order to avoid the issue of the liquid wrapping around the tips when the tips entered the gas stream. This enabled the acquisition of highly consistent peak area ratio results. A constant linear rail speed of 1 mm/s eliminated sample carryover between replicates, in addition to providing baseline separation of signals in the total ion chromatograms. The linear rail was positioned in the middle of the 4 cm space between the mass spectrometer inlet and the ion source. Adjustment of this distance between experimental runs was found to introduce inconsistencies in peak intensities which precluded accurate quantification of analytes.

Preparation of standard curves using calibration standards. A petivericin stock solution of 100 ppm was prepared in Buffer A (20 mM phosphate buffer at pH 8.0 containing 25 µM PLP, 6 mM petiveriin) with 20 ppm internal standard petivericin-d14. Serial dilutions of the 100 ppm stock solution were used to prepare 10 sets of calibration standard samples ranging from 10 to 100 ppm. A pyruvate stock solution of 500 ppm was prepared in Buffer A with 100 ppm internal standard pyruvate-d3. Serial dilutions of the 500 ppm stock solution were used to prepare 11 sets of calibration standard samples ranging from 25 to 400 ppm. A 500 ppm petiveriin stock solution was prepared in Buffer A with 200 ppm of the internal standard S-methyl-L-cysteine. Serial dilutions of the 500 ppm stock solution were used to prepare 11 sets of calibration standard samples ranging from 1 to 500 ppm. Total volume of each calibration standard sample was 500 µL and analyzed in triplicate. Peak integration was performed using the peaks for petivericin (m/z 263.0564), petivericin-d14 (m/z 277.1443), pyruvate (m/z 87.0082), pyruvate-d3 (m/z 90.0270), petiveriin (m/z 228.0694), and S-methyl-Lcysteine (m/z 136.0432). The DART-HRMS peak area ratio (PAR) of petivericin to petivericind14, pyruvate to pyruvate-d3, and petiveriin to S-methyl-L-cysteine were used in the generation of calibration curves to correct for variation in the instrument response to the samples. The PAR for petivericin, pyruvate, and petiveriin are illustrated in Supporting Information Tables S-1, S-2, and S-3, respectively and the standard curves for petivericin, pyruvate and petiveriin are presented in Supporting Information Figure S-3. Alliinase extraction and determination of protein concentration. Alliinase was extracted using a previously reported protocol20 with the following modifications: (1) the extraction buffer did not contain 2-mercaptoethanol (BME) and polyvinylpyrrolidone (PVPP); (2) the protein extract after dialysis was concentrated using Millipore centrifugal filter units (Burlington, MA) with a molecular weight cut off of 10 kDa. Assessment of the concentration of the protein acquired from P. alliacea roots was performed using the Coomassie 5 ACS Paragon Plus Environment

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(Bradford) Protein Assay Kit according to manufacturer specifications. The protein extract concentration was determined to be ~4 µg per gram of fresh roots. Kinetic studies of alliinase activity. The time frame at room temperature during which the alliinase was active was determined by monitoring the production of pyruvate and the sulfine PMTSO using DART-HRMS when 6 mM of the petiveriin substrate was exposed to alliinase in 20 mM phosphate buffer at pH 8.0 containing 25 µM PLP. DART-HRMS spectra were acquired at 15, 30, 45, 60, 75, 90, 105, 120, 150, and 180 min. The samples were analyzed in triplicate. The production of pyruvate and PMTSO were determined by total ion counts. The total ion counts of these compounds and their standard deviations are illustrated in Supporting Information Tables S-4 and S-5. Determination of the factors affecting P. alliacea alliinase activity. Alliinase activity was monitored using petiveriin as the substrate. The 500 µL reaction mixture was comprised of 20 mM phosphate buffer at pH 8.0 containing 6 mM petiveriin, 25 µM PLP, and 40 µg/mL alliinase/LFS (Buffer B). The solution was incubated for 1 h at room temperature and then analyzed using the protocol described in the previous section. The concentrations of pyruvate and petivericin were determined by using the standard curves described previously. Pyruvate (concentrations ranging from 0.5 mM to 8.4 mM) was added to 500 µL of Buffer B. The influence of pyruvate was determined by monitoring the formation of petivericin over the course of 1 h by DART-HRMS. The petivericin concentration was determined from the petivericin/petivericin-d14 standard curve. Petivericin (concentrations ranging from 2 µM to 100 µM) was added to 500 µL of Buffer A. The influence of petivericin was determined by monitoring the formation of pyruvate at 1 h. The pyruvate concentration was determined from the pyruvate/pyruvate-d3 standard curve. To study the influence of the combination of pyruvate and petivericin on alliinase activity, 4.2 mM pyruvate and 110 µM petivericin were added into 500 µL of Buffer B. The influence of a combination of pyruvate and petivericin was determined by monitoring the decrease of the substrate petiveriin over the course of 1 h. Petiveriin consumption was determined using the petiveriin/S-methyl-L-cysteine standard curve. The PAR and relative amounts of petivericin, pyruvate, and petiveriin are illustrated in Supporting Information Tables S-6, S-7, and S-8, respectively.

Results DART-HRMS-facilitated confirmation of alliinase/LFS derived from P. alliacea roots. The P. alliacea alliinase/LFS complex was isolated from plant roots as described in previous work.44 The protein concentration was determined to be ~4 µg per gram of fresh roots. We initiated our enzyme activity studies by confirming the enzyme was active in planta, which was assessed by the observation of substrate (petiveriin) and alliinase-derived products in breached root tissue. Product formation was monitored by DART-HRMS. When freshly cut segments of the plant roots were analyzed by suspending them between the ion source and mass spectrometer inlet, petiveriin in its protonated form was observed in positive ion mode at m/z 228.0694 (Figure 1, Panel A), and the thiosulfinate product petivericin was also observed in its protonated form at m/z 263.0564. Pyruvate [M-H+], another product of this reaction, was detected at m/z 87.0082 in negative ion mode (Figure 1, Panel B). The lachrymatory sulfine phenylmethanethial-S-oxide (PMTSO) was also observed in negative ion mode at m/z 137.0061. These results confirmed the presence of alliinase/LFS and petiveriin in fresh tissue, and that the enzyme was functional, since petivericin, pyruvate and PMTSO were all detected. Determination of alliinase/LFS activity at room temperature by DART-HRMS using isotopically labeled analogues. 6 ACS Paragon Plus Environment

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Analytical Chemistry

To determine whether: (1) alliinase activity decreases over time; and (2) at what time point the enzyme ceases to be active under a given set of conditions, we monitored the formation of pyruvate by DART-HRMS when the enzyme was exposed to petiveriin using the alliinase protein extract obtained from P. alliacea roots. On combining petiveriin with alliinase/LFS (at concentrations representative of that observed in fresh roots (6 mM and 40 µg/mL, respectively), the ion counts of pyruvate were monitored every 15 min over the first 1.5 h, and every 30 min over the next 1.5 h. The results, which are presented in Figure 2, show a modest increase in pyruvate formation during the first 40 min, a more dramatic increase during the next 40 min, and then a plateau within the second h (indicative of cessation of enzyme activity). This showed that over time, alliinase activity was curtailed. PMTSO formation over the same time frame also plateaued, indicating that its production eventually ceased (Supporting Information Figure S-4). To investigate whether it was the build-up of products that impacted alliinase activity, we first investigated the amounts of pyruvate and petivericin that are formed over time in planta when P. alliacea roots are injured. Fresh root-derived alliinase/LFS was exposed to 6 mM petiveriin, and to quantify the products by DART-HRMS, synthesized petivericin-d14 and commercially available pyruvate-d3 were used as internal standards. The standard curves constructed for the quantification of petivericin and pyruvate were based on plots of the peak area ratios (PAR) of the total ion counts of deuterated and non-deuterated petivericin and pyruvate, versus the known concentrations of the non-deuterated compounds. These plots are presented in Supporting Information Figure S-3 and had R2 values of 0.9971 and 0.9959, respectively. Using these standard curves, the concentrations of petivericin and pyruvate observed at 1 h were determined to be 110 µM and 4.2 mM, respectively. Alliinase activity is influenced by a combination of small-molecule downstream products. To determine whether products of alliinase-mediated reactions had an effect on alliinase activity, we assessed the influence of increasing concentrations of these compounds on alliinase activity in the protein extract at physiologically relevant concentrations using DART-HRMS. We first monitored the effect of increasing concentrations of pyruvate by monitoring the formation of petivericin when the substrate petiveriin was exposed to alliinase. Compared with the amount of petivericin formed in the absence of added pyruvate, the addition of increasing amounts of pyruvate (from 0.5 mM to 8.4 mM) resulted in a modest decrease in petivericin formation, from 95% to 71% over 1 h (Figure 3, Panel A). On the other hand, increasing concentrations of petivericin (2 µM to 100 µM) resulted in a decrease in the formation of pyruvate from 77% to 40% over 1 h relative to the control where no petivericin was added (Figure 3, Panel B). These results showed that pyruvate and petivericin each exerted an inhibitory effect on the alliinase activity. We observed the negative effects of petivericin on the alliinase to be more dramatic than that of pyruvate. The more dramatic effect of this alliinase inhibitor aligns with the finding that a number of onion-derived flavones exert a modest negative impact on onion alliinase activity.45 Since both products are formed and are present when alliinase is active in planta, we sought to determine their effect on alliinase activity in the presence of both pyruvate and petivericin. The impact of these compounds on alliinase was assessed by monitoring the change in the amount of petiveriin starting material (after 1 h), relative to the control when these compounds were exposed to alliinase. The amount of petiveriin observed after 1 h under physiologically relevant conditions served as the control. When 4.2 mM pyruvate and 110 µM petivericin (the amounts that were previously determined to be produced after 1 h under physiologically relevant conditions) were exposed to alliinase/LFS separately and as a mixture, the amount of petiveriin starting material that was used up decreased in each case, with the greatest decrease being observed for the mixture. These results are presented in Figure 4. For 4.2 mM pyruvate, the activity of alliinase was reduced to 72% that of the control, and when exposed to 110 µM petivericin, the activity was reduced to 39% that of the control. The activity of the alliinase was further reduced to 35% relative to the control when a mixture of 4.2 mM pyruvate and 110 µM petivericin was used. 7 ACS Paragon Plus Environment

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These results indicated that the downstream products pyruvate and petivericin had an inhibitory effect on the activity of alliinase when added individually. Furthermore, when present as a mixture, as would be the case under physiological conditions, the inhibitory effect was enhanced.

Discussion We demonstrate here how DART-HRMS can be used not only to monitor highly labile organosulfur plant chemical defense compounds, but also how they can be quantified by DARTHRMS to reveal feedback inhibition phenomena such as that illustrated in this work. In the aggregate, the results confirm the presence of a negative feedback loop by which the action of the P. alliacea alliinase in the production of reactive downstream organosulfur compounds such as thiosulfinates, is stymied shortly after its activation (Scheme 2).46 Upon tissue breach, exposure of petiveriin to alliinase results in alliinase-mediated formation of the corresponding transient phenylmethanesulfenic acid (PMSA, Scheme 2).13 PMSA, which serves both as the substrate for the LFS and the precursor to petivericin,20,47 is sequestered by the LFS which in turn catalyzes the explosive formation of the lachrymator PMTSO.48 We propose that this reaction sequence functions as a first line of defense and has the advantage of immediately deterring vertebrate herbivores by inducing tearing and painful irritation of the eyes, nose and lungs that lasts several hours.12 The siphoning off of PMSA by the LFS at the expense of petivericin formation ensures that at the start, large amounts of PMTSO can immediately be deployed prior to the generation of concentrations of petivericin that are significant enough to curtail PMSA production (and by extension, lachrymator production) by the alliinase.12 Since pyruvate and petivericin inhibit the alliinase to varying degrees, the gradual increase in their concentrations eventually results in a significant reduction in alliinase activity. Importantly, the shutting down of alliinase also curtails production of the lachrymator, since the alliinase provides the substrate (i.e. the sulfenic acid PMSA) that the LFS converts to the lachrymator. A second element of the defense strategy involves the antimicrobial effects exhibited by the very thiosulfinate that features prominently in the negative feedback loop. Petivericin and other naturally occurring thiosulfinates, such as allicin found in garlic and 1-propenyl/methyl/propyl thiosulfinates found in onion, have been shown to exhibit a broad spectrum of antibacterial, antifungal and antiviral activity at concentrations that are attained in planta.49-52 The deployment of antimicrobial thiosulfinates and the herbivore deterrent PMTSO occur within seconds of plant wounding, whereas the inhibition of alliinase activity that occurs with increasing concentrations of pyruvate and petivericin occurs approximately 1-2 h post wounding. Thus, the thiosulfinate produced serves a dual role comprised of both antimicrobial and alliinase inhibitory activities. Our observations indicate that one short term mechanism by which plants that exhibit this defense chemistry can curtail the negative impact of a tissue breach is through the rapid deployment of compounds such as the lachrymator and thiosulfinate produced in P. alliacea. Although these compounds are corrosive, the ability of the thiosulfinate to ultimately inhibit the activity of the enzyme that initiates the cascade of reactions that result in their formation (i.e., alliinase) ensures reduced collateral damage. Our observations also may shed light on the heretofore unexplained finding in studies of Alliums and other plants (e.g. (Allium cepa),53-56 garlic (Allium sativum),57,58 Tulbaghia violacea,57 and Albizzia lophantha.59) that alliinases appear to be inactivated before all of the available cysteine sulfoxide substrate has been exhausted. Similar to what we observed in P. alliacea, the alliinases in these plants may be shut down shortly after their activation, by the thiosulfinates that are formed when there is a tissue breach, and this would result in much of the cysteine sulfoxide substrate remaining unreacted. The nature of the enhanced sensitivity of the alliinase to the effects petivericin, as well as the possible impact of various other downstream small-molecule degradation products such as SO2 and elemental sulfur on alliinase activity, are the subjects of continuing investigations in our laboratory. DART-HRMS was well-suited to the investigations described here because: (1) of its ability to detect labile organosulfur compounds without causing their degradation or 8 ACS Paragon Plus Environment

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Analytical Chemistry

transformation to other species; (2) the ability to detect the compounds of interest at the same time within the same experiment; and (3) the ability to allow quantification of the compounds of interest through the added use of isotopically-labeled internal standards. PTR-MS has also been shown to be similarly well-suited to detection of organosulfur natural products. For example, it has been used in combination with isotopic labelling to study sulfur compounds in livestock malodorous manure.60 The utilization of milder approaches such as DART-HRMS for the study of organosulfur compounds in particular has been highlighted by Block, who has demonstrated several examples of erroneous conclusions that have been advanced in earlier studies based on the detection of method-induced artifact formation.1,61,62 However, it is worth noting that the acquisition of the consistent results that enabled quantification by DART-HRMS, particularly when using the Dip-it® tips and linear rail system for semi-automation, required that due attention was given to the sampling protocol. It was found that: (1) a linear rail speed of ≤1mm/s prevented sample carry-over and enabled baseline separation of the peaks in the total ion chromatograms; (2) for the analytes of interest, the application of approximately ≥0.8 ng of sample to each Dipit® tip was required to generate a strong DART-HRMS signal; (3) it was essential that the solvent from the solution that was applied to the Dip-it® tips be allowed to dry prior to DART-HRMS analysis, because when the sample is in liquid form, it wraps around the Dip-it® tips as it enters the DART gas stream, which results in inconsistent amounts of sample being ionized and detected; and (4) it is essential that the sample be applied to the same point on all of the Dip-it® tubes, and that the tubes be mounted in the linear-rail such that the samples on each tube were each similarly exposed to the DART gas stream. In this work, this was accomplished by applying the samples to the tips of the Dip-it® tubes, and visual verification that the tubes in the linear-rail were mounted at the same height. It remains to be seen whether species that produce lachrymators of a chemical class different from sulfines (such as Brassica species plants that produce isothiocyanate lachrymators), utilize a similar negative feedback loop to protect cells at the site of tissue injury. The possibility that other downstream small molecules influence alliinase activity, and the mechanism of the negative feedback inhibition, are under investigation in our laboratory.

Conclusions DART-HRMS can serve as a powerful tool for the detection and tracking of induced and labile organosulfur defense compounds that might be otherwise degraded by other harsher conventional methods. The application of this technique for the molecule tracking, and quantification of such compounds using isotopically-labeled analogues, revealed a novel negative feedback inhibition mechanism whereby products downstream of an alliinase can reduce alliinase activity. The results provide a framework within which heretofore unexplained phenomena observed in the defense chemistry of P. alliacea, onion, garlic, and other plants can be explained. The method described here also illustrates how the tracking of labile organosulfur natural products can be coupled to their quantification by DART-HRMS using deuterated internal standards. The approach can be used to study enzyme kinetics in plant materials, and plant defense chemistry.

Associated Content Supporting Information This document contains: (1) the synthesis protocol and compound characterization for the deuterated internal standard petivericin-d14 (i.e. S-benzyl phenylmethanethiosulfinate-d14) used in this study; (2) a figure showing of the acquisition of mass spectra by DART-HRMS using Dip-it® tips; (3) standard curves for the quantification of the alliinase substrate and the formation of alliinase-mediated reaction products; (4) the results of DART-HRMS monitoring of the production of the lachrymatory sulfine over time; and (5) tables listing the total ion counts and peak area ratios used for creation of the standard curves (along with the associated standard deviations).

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Author Information Corresponding Author *Email: [email protected]. Tel: +1 518 437 3740 Notes The authors declare no competing financial interest.

Acknowledgements Gratitude is extended to the U.S. National Science Foundation (Grant numbers 0239755, 1429329, and 1710221 to R.A.M.) for support of this work. The early work by Quan He and Roman Kubec is acknowledged.

References (1) Block, E. Volatile sulfur compounds in food Vol. 1068 ACS Sym. Ser. Ch.2 2011, 35-63. (2) Block, E.; Putman, D.; Zhao, S. H. Allium chemistry: GC-MS analysis of thiosulfinates and related compounds from onion, leek, scallion, shallot, chive, and Chinese chive J. Agric. Food Chem. 1992, 40, 2431-2438. (3) Haines, B.; Black, M.; Bayer, C. In Biogenic Sulfur in the Environment; ACS, 1989, pp 58-69. (4) Oaks, D. M.; Hartmann, H.; Dimick, K. P. Analysis of sulfur compounds with electron capture/hydrogen flame dual channel gas chromatography Anal. Chem. 1964, 36, 1560-1565. (5) Piluk, J.; Hartel, P. G.; Haines, B. L. Production of carbon disulfide (CS2) from L-djenkolic acid in the roots of Mimosa pudica L. Plant Soil 1998, 200, 27-32. (6) Piluk, J.; Hartel, P. G.; Haines, B. L.; Giannasi, D. E. Association of carbon disulfide with plants, in the family Fabaceae J. Chem. Ecol. 2001, 27, 1525-1534. (7) Puxbaum, H.; König, G. Observation of dipropenyldisulfide and other organic sulfur compounds in the atmosphere of a beech forest with Allium ursinum ground cover Atmospheric Environ. 1997, 31, 291-294. (8) Saghir, A. R.; Mann, L. K.; Bernhard, R. A.; Jacobsen, J. V. Determination of aliphatic monoand disulfides in Allium by gas chromatography and their distribution in the common food species Proc. Am. Soc. Hortic. Sci. 1964, 84, 386-398. (9) Saito, K.; Horie, M.; Hoshino, Y.; Nose, N.; Mochizuki, E.; Nakazawa, H.; Fujita, M. Determination of allicin in garlic and commercial garlic products by gas chromatography with flame photometric detection J. Assoc. Off. Anal. Chem. 1989, 72, 917-920. (10) Sendl, A.; Wagner, H. Isolation and identification of homologues of ajoene and alliin from bulb-extracts of Allium ursinum Planta Med. 1991, 57, 361-362. (11) Block, E. Garlic and other Alliums: the lore and the science; Royal Society of Chemistry, Cambridge, UK, 2010. (12) Kubec, R., Kim, S., Musah, R. A. The lachrymatory principle of Petiveria alliacea Phytochemistry 2003, 63, 37-40. (13) Kubec, R., Cody, R. B., Dane, J. A., Musah, R. A., Schraml, J., Vattekkatte, A., Block, E. Applications of direct analysis in real time−mass spectrometry (DART-MS) in Allium chemistry. (Z)-Butanethial S-oxide and 1-butenyl thiosulfinates and their S-(E)-1-butenylcysteine S-oxide precursor from Allium siculum J. Agric. Food Chem. 2010, 58, 1121-1128. (14) Nawal, G., Malik, K., Naeem, H. A review on Allium cepa and biological transformation of its lachrymatory effect IJARBS 2016, 3(2), 35-42. 10 ACS Paragon Plus Environment

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(15) Silvaroli, J. A., Pleshinger, M. J., Banerjee, S., Kiser, P. D., Golczak, M. Enzyme that makes you cry–crystal structure of lachrymatory factor synthase from Allium cepa ACS Chem. Biol. 2017, 12, 2296-2304. (16) Du, S., Jin, H., Bu, D., Zhao, X., Geng, B., Tang, Chao., Du, J. Endogenously generated sulfur dioxide and its vasorelaxant effect in rats Acta Pharmacol. Sin. 2008, 29, 923. (17) Szabó, C. Hydrogen sulphide and its therapeutic potential Nat. Rev. Drug Discov. 2007, 6, 917. (18) Arakawa, T., Sato, Y., Takabe, J., Masamura, N., Kato, M., Aoyagi, M., Kamoi, T., Tsuge, N., Imai, S., Fushinobu, S. Structure Of Allium lachrymatory factor synthase elucidates catalysis on sulfenic acid substrate bioRxiv 2017. (19) Imai, S., Tsuge, N., Tomotake, M., Nagatome, Y., Sawada, H., Nagata, T., Kumagai, H. An onion enzyme that makes the eyes water Nature 2002, 419, 685. (20) Musah, R. A., He, Q., Kubec, R. Discovery and characterization of a novel lachrymatory factor synthase in Petiveria alliacea and its influence on alliinase-mediated formation of biologically active organosulfur compounds Plant Physiol. 2009, 151, 1294. (21) Spåre, C. G., I. Virtanen, A., Norin, T. The volatile carbonyls and alcohols in the flavour substances of onion (Allium cepa) Acta Chem. Scand. 1961, 15, 1280-1284. (22) Chin, H., Lindsay, R. C. Mechanisms of formation of volatile sulfur compounds following the action of cysteine sulfoxide lyases J. Agric. Food Chem. 1994, 42, 1529-1536. (23) Kice, J. L., Venier, C. G., Heasley, L. Mechanisms of reactions of thiosulfinates (sulfenic anhydrides). I. Thiosulfinate-sulfinic acid reaction JACS 1967, 89, 3557-3565. (24) Kice, J. L., Venier, C. G., Large, G. B., Heasley, L. Mechanisms of reactions of thiosulfinates (sulfenic anhydrides). III. Sulfide-catalyzed disproportionation of aryl thiosulfinates JACS 1969, 91, 2028-2035. (25) Miron, T., Shin, I., Feigenblat, G., Weiner, L., Mirelman, D., Wilchek, M., Rabinkov, A.,. A spectrophotometric assay for allicin, alliin, and alliinase (alliin lyase) with a chromogenic thiol: reaction of 4-mercaptopyridine with thiosulfinates Anal. Biochem. 2002, 307, 76-83. (26) Oae, S., Takata, T., Hae Kim, Y.,. Alkaline hydrolyses of unsymmetrical thiolsulfinates: evidence for selective attacking of hydroxide ion on sulfinyl sulfur atom Tetrahedron Lett. 1977, 18, 4219-4222. (27) Borrelli, F., Capasso, R., Izzo Angelo, A. Garlic (Allium sativum L.): Adverse effects and drug interactions in humans Mol. Nutr. Food Res. 2007, 51, 1386-1397. (28) Friedman, T., Shalom, A., Westreich, M. Self-inflicted garlic burns: our experience and literature review Int. J. Dermatol. 2006, 45, 1161-1163. (29) Leraek, A., Rastogi Suresh, C., Menné, T. Allergic contact dermatitis from allyl isothiocyanate in a Danish cohort of 259 selected patients Contact Derm. 2004, 51, 79-83. (30) Oberle M., W. T., Brisson P. Garlic burn to the face J. Spec. Oper. Med. 2016, 16(4), 80-81. (31) Polat, M., Oztas, P., Yalcin, B., Tamer, E., Gur, G., Alli, N. Contact dermatitis due to Allivum sativum and Ranunculus illyricus: two cases Contact Derm. 2007, 57, 279-280. (32) Vargo, R. J., Warner, B. M., Potluri, A., Prasad, J. L. Garlic burn of the oral mucosa: A case report and review of self-treatment chemical burns J. Am. Dent. Assoc. 2017, 148, 767-771. (33) Bautista, D. M., Hinman, A., Julius, D. In 234th ACS National Meeting, Boston, MA, United States, August 19-23, 2007, 2007, pp AGFD-063. (34) Koizumi, K., Iwasaki, Y., Narukawa, M., Iitsuka, Y., Fukao, T., Seki, T., Ariga, T., Watanabe, T. Diallyl sulfides in garlic activate both TRPA1 and TRPV1 Biochem. Biophys. Res. Commun. 2009, 382, 545-548. (35) Macpherson, L. J., Geierstanger, B. H., Viswanath, V., Bandell, M., Eid, S. R., Hwang, S., Patapoutian, A. The pungency of garlic: activation of TRPA1 and TRPV1 in response to allicin Curr. Biol. 2005, 15, 929-934. (36) Salazar, H., Llorente, I., Jara-Oseguera, A., García-Villegas, R., Munari, M., Gordon, S. E., Islas, L. D., Rosenbaum, T. A single N-terminal cysteine in TRPV1 determines activation by 11 ACS Paragon Plus Environment

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pungent compounds from onion and garlic Nat. Neurosci. 2008, 11, 255. (37) Tsuneo, Y. R., Hidetoshi, I., Tsuchiyoshi F., Kei, N., Tai, K. Enhanced activation of the transient receptor potential channel TRPA1 by ajoene, an allicin derivative J. Neurosci. Res. 2010, 66(1), 99-105. (38) Crespo, E.; Hordijk, C. A.; de Graaf, R. M.; Samudrala, D.; Cristescu, S. M.; Harren, F. J. M.; van Dam, N. M. On-line detection of root-induced volatiles in Brassica nigra plants infested with Delia radicum L. root fly larvae Phytochemistry 2012, 84, 68-77. (39) Danner, H.; Samudrala, D.; Cristescu, S. M.; Van Dam, N. M. Tracing hidden herbivores: time-resolved non-invasive analysis of belowground volatiles by proton-transfer-reaction mass spectrometry (PTR-MS) J. Chem. Ecol. 2012, 38, 785-794. (40) Samudrala, D.; Brown, P. A.; Mandon, J.; Cristescu, S. M.; Harren, F. J. M. Optimization and sensitive detection of sulfur compounds emitted from plants using proton transfer reaction mass spectrometry Int. J. Mass Spectrom. 2015, 386, 6-14. (41) Van Dam, N. M.; Samudrala, D.; Harren, F. J. M.; Cristescu, S. M. Real-time analysis of sulfur-containing volatiles in Brassica plants infested with root-feeding Delia radicum larvae using proton-transfer reaction mass spectrometry AoB PLANTS 2012, 2012, pls021-pls021. (42) Danner, H.; Brown, P.; Cator, E.; Harren, F.; Dam, N.; Cristescu, S. Aboveground and belowground herbivores synergistically induce volatile organic sulfur compound emissions from shoots but not from roots J. Chem. Ecol. 2015, 41, 631-640. (43) Musah, R. A.; Lesiak, A. D.; Maron, M. J.; Cody, R. B.; Edwards, D.; Fowble, K. L.; Dane, A. J.; Long, M. C. Mechanosensitivity below ground: touch-sensitive smell-producing roots in the shy plant Mimosa pudica Plant Physiol. 2016, 170, 1075-1089. (44) Musah, R. A., He, Q., Kubec, R., Jadhav, A. Studies of a novel cysteine sulfoxide lyase from Petiveria alliacea: the first heteromeric alliinase Plant Physiol. 2009, 151, 1304. (45) Li, W.-Q.; Zhou, H.; Zhou, M.-Y.; Hu, X.-P.; Ou, S.-Y.; Yan, R.-A.; Liao, X.-J.; Huang, X.S.; Fu, L. Characterization of phenolic constituents inhibiting the formation of sulfur-containing volatiles produced during garlic processing J. Agric. Food Chem. 2015, 63, 787-794. (46) He, Q. The alliinase and lachrymatory factor synthase systems in Petiveria alliacea State University of New York at Albany 2010, 160. (47) Kubec, R., Kim, S., Musah, R. A. S-Substituted cysteine derivatives and thiosulfinate formation in Petiveria alliacea—part II Phytochemistry 2002, 61, 675-680. (48) He, Q.; Kubec, R.; Jadhav, A. P.; Musah, R. A. First insights into the mode of action of a “lachrymatory factor synthase” – Implications for the mechanism of lachrymator formation in Petiveria alliacea, Allium cepa and Nectaroscordum species Phytochemistry 2011, 72, 19391946. (49) Harris, J. C.; Cottrell, S.; Plummer, S.; Llyod, D. Antimicrobial properties of Allium sativum (garlic) Apppl. Microbio. Biotechnol 2001, 57, 282-286. (50) Pérez-Köhler, B.; García-Moreno, F.; Brune, T.; Pascual, G.; Bellón, J. Preclinical bioassay of a polypropylene mesh for hernia repair pretreated with antibacterial solutions of chlorhexidine and allicin: an in vivo study PLOS ONE 2015, 10. (51) Rehman, F.; Mairaj, S. Antibacterial and antifungal activities of isolated allicin IJPBS 2014, 5, 54-63. (52) Shrivastava, A.; Garg, H. K. Allicin as a dermal antibiotic against microbial infections World J Pharm Res 2015, 4, 1052-1056. (53) Lancaster Jane, E., Shaw Martin, L., Randle William, M. Differential hydrolysis of alk(en)yl cysteine sulphoxides by alliinase in onion macerates: flavour implications J. Sci. Food Agric. 1999, 78, 367-372. (54) Randle, W. M., Bussard, M. L. Streamlining onion pungency analyses HortScience 1993, 28, 60-60. (55) Schwimmer, S., Mazelis, M. Characterization of alliinase of Allium cepa (onion) Arch. Biochem. Biophys. 1963, 100, 66-73. 12 ACS Paragon Plus Environment

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(56) Schwimmer, S. Characterization of S-propenyl-L-cysteine sulfoxide as the principal endogenous substrate of L-Cysteine sulfoxide lyase of onion Arch. Biochem. Biophys. 1969, 130, 312-320. (57) Jacobsen, J. V.; Yamaguchi, Y.; Mann, L. K.; Howard, F. D.; Bernhard, R. A. An alkylcysteine sulfoxide lyase in Tulbaghia violacea and its relation to other alliinase-like enzymes Phytochemistry 1968, 7, 1099-1108. (58) Klein, P., Souverein, C. . The microbiological evaluation of the enzyme-substrate system alliin-alliinase Biochem. Z. 1954, 326(2), 123-131. (59) Schwimmer, S., Hansen, S.E. . Enzymic hydrolysis of bifunctional S-substituted-L-cysteine derivatives Acta Chem. Scand. 1960, 14, 2061-2063. (60) Dalby, F. R.; Hansen, M. J.; Feilberg, A. Application of proton-transfer-reaction mass spectrometry (PTR-MS) and 33S isotope labeling for monitoring sulfur processes in livestock waste Environ. Sci. Technol. 2018, 52, 2100-2107. (61) Block, E.; Dane, A. J.; Cody, R. B. Crushing garlic and slicing onions: detection of sulfenic acids and other reactive organosulfur intermediates from garlic and other alliums using direct analysis in real-time mass spectrometry (DART-MS) Phosphorus Sulfur Silicon Relat. Elem. 2011, 186, 1085-1093. (62) Block, E. In Volatile Sulfur Compounds in Food; ACS, 2011, pp 35-63.

For TOC only

Figure Captions Scheme 1. General outline of defense compound production chemistry illustrated for onion (Allium cepa), Allium siculum and Petiveria alliacea. Exposure of cytoplasmic S-substituted cysteine sulfoxide derivatives to vacuolar alliinase results in cleavage to form sulfenic acids and αaminoacrylic acid. The α-aminoacrylic acid is hydrolyzed to pyruvate, whereas the sulfenic acid can either: (1) condense with a second molecule of sulfenic acid (with loss of water) to form symmetrical or unsymmetrical thiosulfinates; or (2) undergo transformation by lachrymatory factor synthase (LFS) to a sulfine lachrymator. Both the lachrymators and the thiosulfinates undergo further transformations to yield the derivatives shown. Figure 1. DART-HRMS spectra of injured Petiveria alliacea roots at 350 oC. Panel A: positive ion mode. Petiveriin and petivericin were detected at m/z 228.0694 and m/z 263.0564, respectively; Panel

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B: negative ion mode. The pyruvate and sulfine products were detected at m/z 87.0082 and m/z 137.0061, respectively. Figure 2. Activity of alliinase at room temperature as a function of time. The reaction was monitored over a period of 180 min. The plot shows a modest increase of pyruvate formation during the first 40 min, a more dramatic increase during the next 40 min, and then a plateau in the second hour (indicative of cessation of alliinase activity). Figure 3. The effects of pyruvate and petivericin on P. alliacea alliinase activity. Panel A: negative effect of increasing pyruvate concentrations on alliinase activity; Panel B: negative effect of increasing petivericin concentrations on alliinase activity. The effect of pyruvate on the alliinase was determined by monitoring petivercin production (Panel A). The influence of petivericin on the alliinase was determined by monitoring the formation of pyruvate (Panel B). Figure 4. Negative effects of the indicated concentrations of pyruvate and petivericin, as well as a combination of these compounds, on the activity of P. alliacea alliinase/LFS. The influence of pyruvate and petivericin were determined by monitoring the consumption of the substrate petiveriin. Scheme 2. Outline of the feedback inhibition loop involving P. alliacea alliinase. Within seconds of wounding, the exposure of petiveriin to an alliinase/LFS complex results in rapid production of the highly irritating lachrymatory sulfine PMTSO, which causes long-lasting and severe irritation to the eyes, nose and lungs. This serves as a first line of defense in deterring vertebrate herbivores. A second component of the defense strategy involves release of the thiosulfinate petivericin which serves the dual role of curtailing the growth of microbes at the site of the wound pending healing and inhibiting the alliinase. Increasing amounts of petivericin and pyruvate are also gradually formed. The accumulation of pyruvate and petivericin eventually inhibit the activity of the alliinase. The gradual inactivation of the alliinase by these products interrupts the continuous production of the PMTSO, thiosulfinates, and other cytotoxic downstream products such as various oligosulfides.

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Scheme 1. General outline of defense compound production chemistry illustrated for onion (Allium cepa), Allium siculum and Petiveria alliacea. Exposure of cytoplasmic S-substituted cysteine sulfoxide derivatives to vacuolar alliinase results in cleavage to form sulfenic acids and αaminoacrylic acid. The α-aminoacrylic acid is hydrolyzed to pyruvate, whereas the sulfenic acid can either: (1) condense with a second molecule of sulfenic acid (with loss of water) to form symmetrical or unsymmetrical thiosulfinates; or (2) undergo transformation by lachrymatory factor synthase (LFS) to a sulfine lachrymator. Both the lachrymators and the thiosulfinates undergo further transformations to yield the derivatives shown.

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Figure 1. DART-HRMS spectra of injured Petiveria alliacea roots at 350 oC. Panel A: positive ion mode. Petiveriin and petivericin were detected at m/z 228.0694 and m/z 263.0564, respectively; Panel B: negative ion mode. The pyruvate and sulfine products were detected at m/z 87.0082 and m/z 137.0061, respectively.

Figure 2. Activity of alliinase at room temperature as a function of time. The reaction was monitored over a period of 180 min. The plot shows a modest increase of pyruvate formation during the first 40 min, a more dramatic increase during the next 40 min, and then a plateau in the second hour (indicative of cessation of alliinase activity).

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Figure 3. The effects of pyruvate and petivericin on P. alliacea alliinase activity. Panel A: negative effect of increasing pyruvate concentrations on alliinase activity; Panel B: negative effect of increasing petivericin concentrations on alliinase activity. The effect of pyruvate on the alliinase was determined by monitoring petivercin production (Panel A). The influence of petivericin on the alliinase was determined by monitoring the formation of pyruvate (Panel B).

Figure 4. Negative effects of the indicated concentrations of pyruvate and petivericin, as well as a combination of these compounds, on the activity of P. alliacea alliinase/LFS. The influence of pyruvate and petivericin were determined by monitoring the consumption of the substrate petiveriin.

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Scheme 2. Outline of the feedback inhibition loop involving P. alliacea alliinase. Within seconds of wounding, the exposure of petiveriin to an alliinase/LFS complex results in rapid production of the highly irritating lachrymatory sulfine PMTSO, which causes long-lasting and severe irritation to the eyes, nose and lungs. This serves as a first line of defense in deterring vertebrate herbivores. A second component of the defense strategy involves release of the thiosulfinate petivericin which serves the dual role of curtailing the growth of microbes at the site of the wound pending healing and inhibiting the alliinase. Increasing amounts of petivericin and pyruvate are also gradually formed. The accumulation of pyruvate and petivericin eventually inhibit the activity of the alliinase. The gradual inactivation of the alliinase by these products interrupts the continuous production of the PMTSO, thiosulfinates, and other cytotoxic downstream products such as various oligosulfides.

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